Asymmetric magnetization fixture

ABSTRACT

A high resolution sensor for internal combustion engines has symmetric and asymmetric magnetic encoders mounted on a support plate for synchronous rotation with the engine. Hall-effect sensor devices monitor the magnetic fields of the encoders and transmit signals to an Electronic Engine Control Unit. Ignition and fuel injection timing are deduced from the positions of the magnetic encoders. The encoders are magnetized on a fixture which establishes the size, strength, and location of each pole.

This is a division of application Ser. No. 482,693 filed Feb. 21, 1990,now U.S. Pat. No. 5,097,209.

BACKGROUND OF THE INVENTION

This invention relates generally to an ignition spark timing controlsystem, and more particularly to a system having magnetic sensingcapabilities for timing the ignition to the engine shaft position.

Virtually all internal combustion enginess manufactured today include anelectronic control unit which monitors and controls ignition timing.Functions which were once controlled through various mechanical linkagesare increasingly controlled in the electronic control unit. With thiscontrol arrangement, timing of engine spark and fuel injection functionswith the valve of each cylinder can be precisely controlled. Thisprecision provides greater efficiency and responsiveness of engine tovarying conditions of operation.

Distributor sensors used today typically produce one pulse, or onerising edge, for each spark plug to be fired.

Many currently used distributors do not provide information required tocontrol the fuel injection system. Further, such systems do not provideinformation to the electronic control unit to indicate which spark plugis being fired. In such systems, the electronic control unit controlsspark advance with respect to valve and fuel injector timing byestimating engine speed between sensor signals and delaying the sparkfor a calculated time after a sensor signal has been received.

Okada et. al, in U.S. Pat. No. 4,742,811, disclosed an ignition timingcontrol system using three axially adjacent columns of magnets attachedto a shaft. Each magnet column rotates in relation to a Hall-sensorwhich generates a signal at various degrees of shaft rotation. The firstrow of magnets is symmetrically spaced about the column. The second rowis asymetrically spaced; while the third row is symmetrically spaced,but has one pulse which is differentiated from the others by very smallpole reversals at the end of the pulse. Processing of these threesignals through the electronic control unit provides the discriminationcapability necessary to proper functioning of the system.

The disposition of the magnetic columns one above the other in the Okadapatent requires a substantial minimum height for the assembly described.Moreover, the twenty-four symmetrical poles in the first columnindicates that each pole is subtending an angle of fifteen degrees onthe circumference of the column. This rather large pulse to angleequivalence acts to limit the precision of the device function. Theimprecision is overcome by the use of three magnetized columns ratherthan the lesser number.

U.S. Pat. No. 3,373,729, to Lemen, discloses an electronic ignitionsystem for internal combustion engines which uses a disk having aplurality of equally spaced magnets about its periphery. The disk issawed perpendicular to its axis to form a slot having axially opposedmagnets in the disk periphery on both sides of the slot. A Hall-sensorplaced within the slot generates triggering signals according to thefluctuating magnetic field experienced as the disk rotates. This device,in essence, serves to replace the breaker points found in thedistributor of a standard mechanically timed ignition system. Thus, thisinvention eliminates the mechanical contact points together with theirshortcomings, but it does not improve the accuracy of the ignition andfuel injection timing.

The foregoing illustrates limitations known to exist in present devicesand methods. Thus, it is apparent that it would be advantageous toprovide an alternative directed to overcoming one or more of thelimitations set forth above.

Accordingly, a suitable alternative is provided including features morefully disclosed hereinafter.

SUMMARY OF THE INVENTION

In one aspect of the present invention, this is accomplished byproviding a high resolution sensor system for internal combustionengines including: first and second magnetic encoding rings suitablymounted for synchronous movement with the engine; and first and secondsignal pickup means located near the path of movement of the first andsecond magnetic encoder means. The magnetic encoders of this inventionare made on a magnetizing fixture having an electrically conductive wirelaid on a support in a planar serpentine path and further havingmagnetic field modifiers placed within the conductor loops to vary thesize, strength, and location of each magnetic pole formed.

The foregoing and other aspects will become apparent from the followingdetailed description of the invention when considered in conjunctionwith the accompanying drawing figures. It is to be expressly understood,however, that the drawing figures are not intended as a definition ofthe invention, but are for the purpose of illustration only.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a fragmentary partially sectional elevation view of the sensorsystem.

FIG. 2 is a schematic plan view of the magnetic field sensors.

FIG. 3 is a schematic plan view of the two magnetic encoders.

FIG. 4 is a schematic plan view of the retainer device.

FIG. 5 is a sectional view of the retainer seen from line 5--5 in FIG.4.

FIG. 6 is a schematic plan view, from above, of the upper drive hub, thesupport plate, and the drive spring.

FIG. 7 is an enlarged fragmentary plan view of a magnetizing fixtureshowing a single magnetizing loop for a South-North-South cycle.

FIG. 8 shows an elevation view of the same magnetizing figure segment asthat shown in FIG. 7.

FIG. 9 shows the asymmetric magnetization produced by the magnetizationfixture of FIGS. 7 and FIG. 8.

FIG. 10 shows a representation of the analog and digital signalsdetected by the magnetic field sensor from the asymmetric magneticencoder.

FIG. 11 is a plan view of a magnetizing fixture, similar to FIG. 7,showing multiple magnetizing loops for multiple South-North-Southcycles.

FIG. 12 is a plan view of a magnetizing fixture, similar to

FIG. 11, showing multiple magnetizing loops and a different sequence ofmagnetic field modifiers.

DETAILED DESCRIPTION

In FIG. 1, is shown a fragmentary partially sectioned elevation view ofone embodiment of the invention. The high resolution sensing system ispreferably designed to mount on an existing automobile distributor base;however, it could as well be mounted anywhere on or in the engine whereit could be driven synchronously with the crankshaft or cam shaft of theengine.

In this embodiment is seen the distributor shaft 1, which serves todrive the rotary member of the sensor system, protruding through thestationary distributor base 2, upon which is mounted the sensor housing30. The high resolution magnetic encoder 10 and the low resolutionmagnetic encoder 15 are mounted on support plate 20 which rides onbearing/spacer 35. The encoder rings 10 and 15 are attached to thesupport plate using retainer ring 21 which has projecting studs 22 whichprotrude through holes in the support plate 20 and drive spring 40. Thestuds 22 of retainer 21 are upset, threaded, or otherwise secured tocapture the assembly.

High resolution sensor 11 and low resolution sensor 16 are mounted atappropriate radial locations to provide alignment with the highresolution magnetic encoder 10 and low resolution magnetic encoder 15,respectively. The sensors are Hall-effect transducers which provideappropriate output regardless of speed of motion. The signals generatedin the sensors are transmitted to the electronic control unit of theengine.

Upper drive hub 41 is coupled to the distributor shaft by which it isrotatively driven. Drive spring 40 extends from the upper drive hub 41to the support plate 20 and provides the driving connection between thetwo plates. Drive spring 40 is so designed that it accommodates smallvertical displacements of distributor shaft 1 without causing anyrelative rotation between upper drive hub 41 and support plate 20. Thisfeature is required to avoid changes of timing which could otherwise beinduced by vertical movement of the distributor shaft 1.

A cover 51 is provided to protect the sensor system from damage orcontamination. Optional seals 52 are provided for the interface betweencover 51 and distributor shaft 1 as well as sensor housing 30 anddistributor shaft 1. The seals may be O-rings or other suitable sealingdevices. The cover 51 is placed on the housing 30 and secured withadhesive or other appropriate sealing means. The underside of housing 30is filled with a castable encapsulant 50 which protects the printedwiring board and other electronics of the sensor system.

High resolution sensor 11 and low resolution sensor 16 are shownschematically in a plan view in FIG. 2. Here, it can be seen that thehigh resolution sensor consists of two Hall-effect transducers and theirassociated electronics. This provides high resolution by doubling thenumber of signals generated in the sensors in response to each magneticpole reversal on the high resolution magnetic encoder ring 10. Only oneHall-effect transducer is used on low resolution sensor 16.

FIG. 3 shows a schematic plan view representative of high resolutionmagnetic encoder ring 10 and low resolution magnetic encoder ring 15.High resolution encoder ring 10 has a large number of magnetic poles. Inthe preferred embodiment, this ring will have 360 poles, but it couldhave more or fewer as the engine design requires. Low resolutionmagnetic encoder ring 15 is shown with sixteen poles, as an example, fora four-cylinder engine. There are four sharp North poles, eightintermediate South poles, and four very weak, very diffuse North poles.The four sharp North poles, one for each cylinder, are used to indicatewhich cylinder requires either spark or fuel. This is done by providingpoles of different angular extent. For instance, it would be possible tohave poles of one degree, two degrees, three degrees, and four degreesto indicate the respective cylinders to which they apply. Thus, in afour cylinder engine, the three degree magnet would correspond to thenumber three cylinder. Note that all timing is done on the rising edgeof the magnetic pulse.

Retainer ring 21 is shown in FIGS. 4 and 5. From these, it is seen thatmagnet retainer ring 21 is annular in shape and has a "T"-cross-section.In addition, it has a plurality of projecting studs 22 which are used tosecure the ring and the magnets to the thrust washer plate or supportplate 20. Depending on the magnet mounting scheme employed, the retainerring may also be made with an "L"-cross-section.

The projecting studs 22 protrude through the gap between the two magnetrings 10 and 15, through support plate 20, and through drive spring 40.Drive spring 40 transmits the rotary driving force between upper driveplate 41 coupled to distributor shaft 1, and support plate 20. It isalso maintains firm contact between support plate 20 and bearing/spacer35.

FIG. 6 shows a schematic plan view of upper drive hub 41, drive spring40, lower drive plate 42, and projecting studs 22. Spring 40 is shownhere as having three legs, but it could as well have been shown withmore or fewer legs depending on design requirements.

FIGS. 7 and 8 show a plan view and an elevation view of a section of afixture 90 used for asymetrically magnetizing the low resolutionmagnetic encoder ring. It consists of a steel base plate 89 upon whichis placed an eletrically conductive wire 98 in a planar sertpentinepattern along the surface of the fixture. The sizes of the individualloops in the conductor wire 98 are determined by the size of magneticpole desired at that loop. When magnetizing an article on this fixture,the article would be placed flat on top of the fixture. When a pulse ofvery high amperage is passed through conductor 98, magnetic poles areproduced in steel base plate 89 and in the magnetic material that hasbeen placed on top of the fixture. The aluminum or plastic mangeticfield modifier 96 serves a dual purpose. First, it acts as a spacer forthe loop in the conductor wire 98; and second, if aluminum, it serves toslightly reduce the strength of the North pole produced in the workpiece being magnetized above the area within the loop of conductor wire98. The steel magnetic field modifiers 94 serve to intensify the strenthof the magnetic poles induced in the work piece above the modifiers,while the aluminum magnetic field modifiers 92 serve to reduce thestrength of the poles, and indeed cause a squeezing or a sharpening ofthe poles above the steel field modifiers 94.

Note that steel modifiers intensify the field strength of the poleformed above them; air or plastic is essentially neutral, neitherintensifying nor weakening the field; while aluminum serves toessentially repel the field, or cause it to distort so that itconcentrates more in the regions adjacent to the intensifying or neutralmodifiers. Thus, by proper selection of the amperage and duration of themagnetizing current pulse, the sizes of the loops in the conductor wire98, the sizes and placement of the magnetic field modifiers 92, 94, and96, and the selection of material and the sequence of placement of themagnetic field modifiers, the sizes, strengths, and locations of themagnetic poles on the work piece being magnetized can be very accuratelycontrolled.

FIG. 9 is a schematic representation of the magnetic pole array producedby the asymmetrical magnetizing fixture of FIGS. 7 and 8. The strongNorth pole 106 is produced at the center of the fixture segment shown inFIGS. 7 and 8. The somewhat weaker and sharper South poles 104correspond to the placement of the steel magnetic field modifiers 94while the South 104 to weak North pole 100 boundary 102 occursapproximately above the aluminum magnetic field modifiers 92. Themagnetic flux from any one of the magnetic poles is proportional to thefield strength of that pole. In a magnetized ring, the total magneticflux from all the North poles must equal the total magnetic flux from,or into, all of the South poles. Thus, in the curve shown in FIG. 9 themagnetic field strength is represented by the vertical axis, and themagnetic flux is proportional to the area of the curve above or belowthe horizontal axis. If all the poles on a circular magnetic ring wererepresented in a figure such as this, the total area under all the Northpoles would be equal to the total area over all the South poles.

FIG. 10 shows a schematic representation of the analog 120 and digital130 signal resulting from one revolution of the low resolution magneticencoder 15. The analog trace 120 represents the raw output of the Hallsensor. The digital trace 130 represents that same output afterconditioning of the signal in the sensor circuitry. These tracesillustrate the asymmetry which provides the discrimination that permitsthe proper cylinder to receive the spark signal. In this case, everyother pulse subtends two degrees of angle. Pulses 122 and 126 are eachtwo degree pulses, while pulses 124 and 128 are seven degree and twelvedegree pulses, respectively. The analog, or unconditioned, signalindicates a total of sixteen poles, or eight dispoles for the fullmagnetic encoder ring. The digital trace 130 shows only four pulsesgenerated by these sixteen poles. This is accomplished by the signalconditioning which is designed to only recognize positive, or North,magnetic field strengths having greater magnitudes than those of thediffuse North poles 115. Thus, the digital trace 130 only recognizes thefour strong North poles 122, 124, 126, and 128. Hence, only four plusesare transmitted to the electronic control unit by the low resolutionsensor circuit for each revolution of the low resolution encoder ring15. The timing function is controlled from the rising of each pulsewhile the discrimination function is determined by the angular width ofeach pulse.

The high resolution magnetic encoder ring 10 is, of course, turningsynchronously with the low rersolution magnetic encoder ring 15. Sincethe high resolution encoder ring 10 has 360 poles, and since it has twohigh resolution magnetic field sensors 11 associated with it, there are720 pulses produced for each revolution of the high resolution encoderring 10. This provides half degree resolution without interpolations,and even closer resolution with interpolations.

FIGS. 11 and 12 are plan views similar to FIG. 7 but showing a largerportion of the fixture 90 used for asymmetrically magnetizing the lowresolution magnetic encoder ring. Those figures illustrate thepreviously described planar serpentine pattern of the conductive wire 98along the base plate 89 as well as alternative sequences of the magneticfield modifiers 92, 94, and 96 to achieve the desired size, strength andlocations of the magnetic poles.

Having described the invention, what is claimed is:
 1. A fixture formagnetizing a magnetic material to produce magnetic poles of non-uniformstrength, the fixture comprising:a support; an electrically conductivewire disposed in a planar serpentine path on said support forming aplurality of serpentine loops; and a plurality of magnetic fieldintensifiers and magnetic field suppressors, the magnetic fieldintensifiers and magnetic field suppressors being placed in the areas ofsaid support between the serpentine loops of the conductive wire wherebythe strength of adjacent magnetic poles produced in non-uniform.
 2. Afixture according to claim 1 wherein the strength of a magnetic polebeing produced is greater than the strength of adjacent magnetic polesbeing produced.
 3. A fixture according to claim 1 wherein the magneticfield suppressors are diamagnetic material.
 4. A fixture according toclaim 1 wherein the magnetic field intensifiers are ferromagneticmaterial.
 5. A fixture according to claim 1 wherein a spacer material islocated within a first serpentine loop, magnetic field intensifiersbeing located in the adjacent serpentine loops and proximate the firstserpentine loop, and magnetic field suppressors being located in theadjacent serpentine loops proximate the magnetic field intensifiers anddistal the first serpentine loop.
 6. A fixture according to claim 5wherein said spacer material is selected from the group consisting ofair, plastic, aluminum and steel depending upon the desired strength ofthe magnetic pole produced by said first serpentine loop.
 7. A fixtureaccording to claim 1 wherein a spacer material is located within a firstserpentine loop, magnetic field suppressors being located in theadjacent serpentine loops and proximate the first serpentine loop, andmagnetic field intensifiers being located in the adjacent serpentineloops proximate the magnetic field suppressors and distal the firstserpentine loop.
 8. A fixture according to claim 7 wherein said spacermaterial is selected from the group consisting of air, plastic, aluminumand steel depending upon the desired strength of the magnetic poleproduced by said first serpentine loop.
 9. A fixture according to claim1 wherein a magnetic field intensifier and a magnetic field suppressorare located within a first serpentine loop.
 10. A fixture according toclaim 9 wherein the magnetic field intensifier in the first serpentineloop is proximate a magnetic field intensifier in an adjacent serpentineloop and the magnetic field suppressor in the first serpentine loop isproximate a magnetic field suppressor in an adjacent serpentine loop.11. A fixture for magnetizing a magnetic material to produce magneticpoles of non-uniform strength, the fixture comprising:a support; anelectrically conductive wire disposed in a planar serpentine path onsaid support forming a plurality of serpentine loops; a spacer material;and a pluality of magnetic field intensifiers and magnetic fieldsuppressors, the spacer material is located within a first serpentineloop, the magnetic field suppressors being located in the adjacentserpentine loops and proximate the first serpentine loop, and themagnetic field intensifiers being located in the adjacent serpentineloops proximate the magnetic field suppressors and distal the firstserpentine loop whereby the strength of adjacent magnetic poles producedis non-uniform.
 12. A fixture according to claim 11 wherein the magneticfield suppressors are diamagnetic material.
 13. A fixture according toclaim 11 wherein the magnetic field intensifiers are ferromagneticmaterial.
 14. A fixture according to claim 11 wherein said spacermaterial is selected from the group consisting of air, plastic, aluminumand steel depending upon the desired strength of the magnetic poleproduced by said first serpentine loop.
 15. A fixture for magnetizing amagnetic material to produce magnetic poles of non-uniform strength andnon-uniform spacing, the fixture comprising:a support; an electricallyconductive wire disposed in a planar serpentine path forming a pluralityof serpentine loops on said support, the serpentine loops havingnon-uniform spacing; and a plurality of magnetic field intensifiers andmagnetic field suppressors the magnetic field intensifiers and magneticfield suppressors being placed in the areas of said support between theserpentine loops of the conductive wire whereby the strength of adjacentmagnetic poles produced is non-uniform and the spacing of the magneticpoles produced in non-uniform.
 16. A fixture according to claim 15wherein the magnetic field suppressors are disamagnetic material.
 17. Afixture according to claim 15 wherein the magnetic field intensifiersare ferromagnetic material.